Ranjit Nayak

@astu.edu.et

Assistant Professor
Adama Science and Technology University



           

https://researchid.co/nayakranjit
10

Scopus Publications

Scopus Publications


  • Influences of subduction derived fluids and melt in the genesis of Nidar ophiolite peridotites, Ladakh Himalaya, India: Evidence from mineralogy, PGE and Nd isotopic compositions
    Ranjit Nayak, Debasis Pal, Sakthi Saravanan Chinnasamy, Manavalan Satyanarayanan, Santosh Kumar, Jitendra Dash, Pratap Chandra Sethy, and Akhin Mohan
    Elsevier BV

  • PGE geochemistry and platinum-group minerals in chromitites from Indus Suture Zone ophiolite, northwest Himalaya, India
    Ranjit Nayak, Debasis Pal, Sakthi Saravanan Chinnasamy, and Manavalan Satyanarayanan
    Springer Science and Business Media LLC

  • Geoheritage in Ladakh Himalaya: the Indus Suture Zone Ophiolites, Southeast of Ladakh, India
    Ranjit Nayak and Shankar Karuppannan
    Springer Science and Business Media LLC

  • Low-titanium clinopyroxene composition of Nidar ophiolite gabbros, southeastern Ladakh Himalaya, India: implications to geotectonic setting
    Ranjit Nayak and Debasis Pal
    Current Science Association
    The Nidar ophiolite complex is one of the wellpreserved ophiolite sequences of the Indus Tsangpo Suture Zone (ITSZ) towards the southeastern part of Ladakh Himalaya, India. This study presents petrography and clinopyroxene mineral chemistry of gabbroic rocks from the Nidar ophiolite. These gabbros are massive, essentially composed of plagioclase and clinopyroxene with minor amounts of olivine, orthopyroxene, hornblende and magnetite. The clinopyroxenes are very low in TiO2 (0.05–0.77 wt%) and Na2O (0.12–0.85 wt%) but rich in SiO2 (52–55 wt%). It is observed that there is a wide variation of CaO (12.26– 23.88 wt%) and in the Wo–En–Fs ternary diagram, clinopyroxene shows augitic to diopside compositional variation. These low-titanium clinopyroxenes are inferred to be tholeiitic in nature with an island-arc boninitic affinities.

  • An island arc origin of Jurassic plagiogranite in the Shiquanhe ophiolite, western Bangong Suture, Tibet: Zircon U–Pb chronology, geochemistry, and tectonic implications of Bangong Meso-Tethys
    Wei Li, Nina Liu, Ranjit Nayak, Yaoliang Ma, Jinjun Wang, Xichong Hu, Jiehui Pang, Weile Huang, Yun Zhong, and Weiliang Liu
    Wiley
    The plagiogranites in ophiolites are minor in volume but can provide crucial information for the origin and tectonic evolution of ancient oceanic lithosphere. This paper presents the geochronology and geochemistry of a newly discovered plagiogranite in the Shiquanhe ophiolite, from the west end of the Shiquanhe‐Jiali ophiolite sub‐belt, Bangong Suture, central Tibet. Zircon U–Pb dating of two samples yields Middle Jurassic ages (167.4 ± 1.2 Ma and 167.5 ± 1.5 Ma). The plagiogranite has positive whole‐rock εNd(t) (4.2–4.9) and zircon εHf(t) (9.6–14.3) values, high Th/Nb ratios (0.6–2.8) but relatively low La/Nb ratios (0.9–9.9), indicating that it was possibly derived from a depleted mantle with the contribution of minor subducted sediments. The LREE‐enrichment but HREE‐flat patterns with negative Eu anomalies and negative Nb‐Ti anomalies resemble those of shear‐type plagiogranites, which mean that this rock was likely formed by partial melting of metabasite. Combined with the plagiogranite which does not exhibit chilled contacts against the Shiquanhe ophiolitic metabasite, suggests that the plagiogranite may have been derived from the associated ophiolitic metabasite. Geochemical calculating and modelling indicate that the plagiogranite was possibly produced by a low degree (<10%) partial melting of metabasite and replenished by minor sediments melts at low temperature (<800 °C) and low pressure (<0.1 GPa) conditions. The Shiquanhe plagiogranite, together with the contemporaneous Lagkorco plagiogranite in the same ophiolite sub‐belt, indicates that an intra‐oceanic island arc system was developed in the Bangong Meso‐Tethys during the Middle Jurassic.


  • Petrological study of spinel peridotites of Nidar ophiolite, Ladakh Himalaya, India
    Ranjit Nayak and Bidyananda Maibam
    Springer Science and Business Media LLC

  • Genesis and tectonic implications of cumulate pyroxenites and tectonite peridotites from the Nagaland–Manipur ophiolites, Northeast India: constraints from mineralogical and geochemical characteristics
    A. Krishnakanta Singh, R. Nayak, S. Khogenkumar, K. S. V. Subramanyam, S. S. Thakur, R. K. Bikramaditya Singh, and M. Satyanarayanan
    Wiley
    The Nagaland–Manipur ophiolites (NMO) of Northeast India forms a part of the Tethyan ophiolites and comprises a suite of tectonite peridotites and cumulate mafic–ultramafic sequence with mafic extrusive–intrusive rocks, felsic intrusives and oceanic pelagic sediments along with minor podiform chromitites. However, sheeted dykes, which are considered as a significant component of ophiolites, are absent in the NMO. The tectonite peridotites are distinguished from the cumulate pyroxenites by the presence of pyroxene lineation, deformed bands and strained extinction in olivine, kink twin lamellae in pyroxene. Both the tectonite peridotites and cumulate pyroxenites contain aluminous spinel with Cr number [Cr# = Cr/(Cr + Al)] in the range of 0.14 to 0.29 and 0.27 to 0.48, respectively. Mg number [Mg# = Mg/(Mg + Fe2+)] in Cr‐spinel is higher in tectonite peridotites (0.71–0.76) than cumulate pyroxenites (0.44–0.53). Chondrite‐normalized rare earth elements (REE) patterns of cumulate pyroxenites exhibit depleted at light REEE (LREE) (LaN/SmN = 0.380–0.759) but flat middle REE (MREE) to heavy REE (HREE) (SmN/YbN = 0.622–0.756). However, the tectonite peridotites show gradual decrease in concentrations from HREE to MREE (SmN/YbN = 0.285–0.460) and slight increase in LREE (LaN/SmN = 0.721–2.201). The cumulate pyroxenites show strong enriched PPGE patterns and higher PGE concentrations (∑PGE = 85.8–163.5 ppb) compared with the tectonite peridotites (∑PGE = 34.8–113.0 ppb). The estimated equilibration temperature ranges from 890 to 931 °C for cumulate pyroxenites and 971 to 1156 °C for tectonite peridotites. The olivine–spinel equilibrium along with Cr‐spinel chemistry and PGE data suggests that the tectonite peridotites represent the residual mantle left after limited extraction of basaltic melts by low‐degree partial melting (<15%). Conversely, the presence of highly magnesian orthopyroxene and clinopyroxene in the cumulate pyroxenites in conjunction with their geothermometry suggests that they were formed at high pressure and temperature by magmatic fractionation from the basaltic melt. The geochemical data together with field and petrographical evidences indicate that both the tectonite peridotites and cumulate pyroxenites are essentially spinel‐bearing and devoid of plagioclase, suggesting their derivation in the mantle beyond the stability limit of plagioclase in a mid‐oceanic ridge tectonic setting. We conclude that the ultramafic sequence of the NMO was initially generated at a mid‐oceanic ridge tectonic setting close to the eastern boundary of the Indian passive margin and then thrust over the continental margin of the Indian Plate towards the west during its collisional and subduction process with/beneath the Myanmar Plate. Copyright © 2016 John Wiley & Sons, Ltd.